KR100717251B1 - Record carriers with stereo and data signals - Google Patents

Abstract

The present invention relates to a recording medium having a stereo signal and a data signal. The data signal includes a first portion and the remaining portion. The first channel on the record carrier comprises a composite signal. The composite signal is obtained by combining the stereo signal and the first portion of the data signal, preferably using an embedded data technique. The second channel on the record carrier comprises the remainder of the data signal. Moreover, the present invention relates to a method for recording / reproducing a stereo signal and a data signal on a recording medium, a recording apparatus and a reproduction apparatus.

Record carrier, stereo signal, data signal, embedded data technology, multichannel extension signal

Description

Recording medium having stereo signal and data signal {RECORD CARRIER CARRYING A STEREO SIGNAL AND A DATA SIGNAL}             

The present invention relates to a recording medium having a stereo signal and a data signal, wherein the stereo signal is recorded in a first channel on the recording medium.

Moreover, the present invention relates to a method for recording a stereo signal and a data signal on the recording medium, a recording apparatus for performing the above method, and a reproducing apparatus for reproducing a stereo signal and a data signal.

The above-described recording medium and apparatus are known from EP-A-0 372 601. The first channel on a conventional record carrier has a constant data capacity to have a stereo signal and a data signal. The above document discloses a general method for embedding a data signal inside a stereo signal. Sometimes the data capacity of the first channel is not sufficient to have both a stereo signal and a data signal without degrading the signal quality too much.

After all, an object of the present invention is to provide a recording medium capable of carrying a stereo signal and a data signal while having an increased data capacity for the stereo signal and the data signal.

In the recording medium according to the present invention, the data signal includes a first portion and the remaining portion, wherein the first portion is combined with the stereo signal to obtain a composite signal recorded in the first channel on the recording medium. The remaining part is recorded in the second channel on the recording medium.

In one embodiment of the record carrier, the record carrier is characterized in that the first channel is represented by a first variation of the first physical parameter of the record carrier and the second channel is represented by a second variation of the second physical parameter of the record carrier. And the second physical parameter is different from the first physical parameter.

The recording method according to the present invention is defined as described in claims 12 to 17. The recording apparatus according to the present invention corresponds to the subject matter of claim 18, and the playback apparatus according to the present invention corresponds to the subject matter of claims 19 to 26.

The present invention is based on the idea that implementing a second channel on a record carrier can increase the data capacity for recording stereo and data signals on the record carrier. Such increased data capacity can be used to enable recording of data signals at increased data rates. It is also possible to record a multichannel signal in addition to the stereo signal on the recording medium. For example, by using a buried channel technique, a channel embedded in the stereo signal is generated to accommodate the first portion of the data signal. In some cases, the data capacity of the first channel is not sufficient to hold the entire data signal. Thus, the second channel is used to hold the rest of the data signal. Note that recording media having such a second channel are known from USP 5,210,738 and USP 5,724,327 (PHN 13922). However, the above documents do not describe that the data capacity of the inserted channel is not sufficient to hold the data signal. Further, the above document does not suggest a solution for increasing the data capacity on the recording medium required to hold the data signal.

These and other inventions of the present invention will become apparent from the following examples given with reference to the accompanying drawings in which:

1 shows an embodiment of a recording apparatus,

2 shows an embodiment of a playback apparatus,

FIG. 3 shows another embodiment of the first and second recording means of the recording apparatus shown in FIG.

FIG. 4 shows another embodiment of the first and second reading means of the playback apparatus shown in FIG.

FIG. 5 shows a second embodiment of the first and second recording means of the recording apparatus shown in FIG.

FIG. 6 shows a second embodiment of the first and second reading means of the playback device shown in FIG.

1 shows a first embodiment of a recording apparatus according to the present invention. The recording apparatus is configured to record stereo signals and data signals, wherein the data signals correspond to multichannel extension signals. The multichannel extension signal includes at least one signal such as a center signal, a mono surround signal, a surround left signal, a surround right signal, or a four-channel surround signal. The apparatus has a first input terminal 2 for receiving a stereo signal and a second input terminal 4 for receiving a multichannel extension signal. The stereo signal and the multichannel extension signal are preferably sampled at a frequency of 44.1 kHz. The second input terminal is connected to the input 6 of the data compression section 8. The data compression unit is configured to compress the multichannel extension signal and to supply the data compressed multichannel extension signal to the output 10. The special form of data compression performed in the data compression unit is not essential for the present invention. The output 10 of the data compression section 8 is connected to the input 12 of the divider 14. The divider 14 is configured to divide the received and compressed multichannel extension signal into a first portion for supplying to the first output 16 and the remaining portion for supplying to the second output 18. The device has a first input 22 connected to a first input terminal 2, a coupling having a second input 24 and an output 26 connected to a first output 16 of a divider 14. It further comprises a part (20). This combiner is configured to combine the first portion of the received stereo signal and the compressed multichannel extension signal, preferably using an embedded data technique. Insertion data techniques are well known in the art. These techniques allow the insertion of data channels inside stereo signals. When the stereo signal comprises left and right channels, for example, each consisting of 16 bits / sample, the average of 5 bits / sample without degrading the perceived audio quality of the 16 bits / sample of the left and right signals. A data signal with a capacity can be obtained. Another suitable method is disclosed in EP-A-0 372 601. In the above document, a so-called hidden channel method for inserting additional information inside a digital audio signal is disclosed.

This apparatus has a first recording section 28. The input 30 of the first recording section is connected to the output 26 of the coupling section 20. The first recording section is configured to record the received composite signal of the first portion of the stereo signal and the data compressed multichannel signal to the first channel of the recording medium 32. The recording medium is preferably a standard audio CD, and the recorded stereo signal in the first channel can be reproduced by a conventional CD player. In this case, the first channel consists of a plurality of optically detectable marks inside the track, whereby the plurality of optically detectable marks have the form of so-called pits.

The apparatus further includes a second recording section 34. The input 36 of this recording section 34 is connected to the second output 18 of the division section 14. The second recording section is configured to record the remaining portion received at the input 36 in the second channel of the recording medium 32. The second channel is preferably recorded by the variation of the track. In USP 5,724,327 several embodiments of a second channel are disclosed.

The operation of the above device will be described in more detail. The second input terminal 4 receives the multichannel extension signal. The multichannel extension signal includes, for example, a left signal, a right signal, a center signal, a surround left signal, and a surround right signal, and has a sample frequency of 44.1 kHz. Next, the multichannel extension signal is data compressed by the data compression section 8. The compression unit preferably includes a perceptual encoder, such as an MPEG-2 audio encoder, for compressing the multichannel extension signal to obtain a data compressed multichannel extension signal. A data compressed multichannel extension in the form of an MPEG stream generated by a standard MPEG-2 audio encoder requires excellent signal quality corresponding to a bit rate of 385 Kbit / sec. More complex MPEG encoders can output MPEG streams containing high quality signals at 320 Kbit / s.

The stereo signal received at the first input terminal 2 is given to the combiner 20. Stereo signals include left and right signals and have a sample frequency of 44.1 kHz. At this time, the left signal inside the stereo signal may be any combination of the left signal, the center signal and the surround left signal or the mono surround signal, and the right signal inside the stereo signal may be the right signal, the center signal and the surround right signal or the mono surround signal. Can be any combination of Inside the combiner 20, the stereo signal, for example using embedded data techniques, to determine the bits within the signal that can be used for the embedded data channel without degrading the perceived quality of the stereo signal. Is analyzed. For standard audio CDs, the left signal as well as the right signal have 16 bits / sample. By inserting a data signal into an embedded data technology, i. On average, this data capacity corresponds to 5 bits / sample. The minimum data capacity is 2 bits / sample and is obtained for very low level signals. Therefore, the data capacity of the inserted channel is on average 2 x 5 x 44.1 kHz = 441 kbit / s with a minimum of 176.4 kbit per second. Thus, the minimum data capacity (= 176.4 kbit / s) using the embedded data technology is not sufficient to hold a multi-channel extended signal compressed in the form of an MPEG stream with good signal quality (= 384 kbit / s).

As mentioned above, a second channel on the record carrier may be used. Some embodiments of the second channel are disclosed in USP 5,724,327 (PHN 13.922). In the case where the audio sample includes 16 bits, a data capacity of almost 2 bits / audio sample can be obtained by variation in the width of the plurality of optically detectable marks. Thus, for a standard audio CD, this means a capacity of 2 x 2 x 44.1 kHz = 176.4 kbit / s. Along with the capacity of the inserted channel in the first channel, the record carrier can hold a signal having a bit rate of at least 352.8 kbit / s, an average signal having a bit rate of 617.4 kbit / s. This full capacity is sufficient to hold most MPEG streams with good quality generated by the MPEG2 audio encoder.

In order to distribute the data compressed multichannel extension signal over the inserted data channel and the second channel in the stereo signal, the data compressed multichannel extension signal is divided into a first part and the remaining part by the divider 14. . Such division may be done by demultiplexing the data compressed multichannel extension signal. Multiplexing can be done by repeatedly applying 5 bytes of the data-compressed multichannel extension signal to the first portion and applying 2 bytes to the remaining portion. It is also possible to employ an adaptive multiplexer in which the distribution is adaptively controlled. The first portion is fed to the combiner 20 and combined to obtain a composite signal, for example by using stereo signals and embedded data techniques. The first recording section records the composite signal in the first channel on the recording medium. The first channel may be recorded on the recording medium, for example, by a first variation of the first physical parameter of the recording medium having the form of a plurality of optically detectable marks alternating with the intermediate region. The plurality of optically detectable marks may have the form of so-called pits on a standard CD. A plurality of optically detectable marks are disposed along the track. The second recording section records the remaining portion in the second channel on the recording medium. The second channel can be recorded on the recording medium by a second change in the second physical parameter in the form of a change in the optically detectable mark across the track echo, for example a change in the width of the plurality of marks. have.

An advantage of the recording device according to the invention is that it reproduces stereo signals by playing back a record carrier, for example a CD, which can be used in a CD player according to the current CD standard. The CD player can read only the first channel, thus the composite signal. The composite signal has the form of a stereo signal. By using the embedded data technique, the perceptible quality level of the stereo signal inside the composite signal is not degraded. As a result, the user hears a signal quality equal to the quality of a stereo signal having almost no inserted data channel.

Another advantage of the recording medium according to the present invention is that the entire contents on the recording medium cannot be reproduced using a commercially available CD recorder. These CD recorders can read the first channel, but not the second channel. The replica produced by the CD recorder contains only the first portion of the composite signal, and thus the multichannel extension signal. As a result, the multichannel data signal cannot be reproduced from the above-described copy, thereby providing copy protection means.

2 shows a first embodiment of a reproduction apparatus for reproducing a stereo signal and a data signal from a recording medium according to the present invention. In this embodiment, the data signal corresponds to a multichannel extension signal. The apparatus has a first reading section 40 for reading the composite signal recorded in the first channel on the recording medium 42 and for supplying the composite signal to the output 44. This first channel is preferably in the form of a channel having a stereo signal of 16 bits / sample on a standard CD. The output 44 of the first reading section 40 is connected to the first output terminal 46 of the device via the converter section 74. The converter converts the composite signal into a stereo signal. The first output terminal 46 can, for example, be connected to a power amplifier, equalizer or speaker.

The output 44 of the first reading section 40 is further connected to the input 48 of the extracting section 50. The extractor 50 is configured to extract a first portion of the data compressed multichannel extension signal from the composite signal received at the input 48 and to supply the first portion to the output 52.

The apparatus further comprises a second reader section 54 for reading the remainder of the data compressed multichannel signal recorded in the second channel of the record carrier 42 and supplying the remainder to the output 56. do. The second channel preferably has the form of a second variation of the second physical parameter of the record carrier, wherein the second variation of the second physical parameter is of the first physical parameter used to hold the first channel on the record carrier. It is different from the first variation. USP 5,724,327 (PHN 13.922) discloses some possible embodiments of the second channel. The above documents describe variations in the position of the track on the recording medium, variations in the width or depth of peaks in the track, or variations in the frequency of the recovered data clock. The second reading unit is configured to detect the second physical parameter described above and output the remaining portion in response to the detected second physical parameter. The output 56 of the second readout 54 is connected to the first input 58 of the combiner 60. The output 52 of the extractor 50 is connected to the second input 62 of the combiner 60. The combiner 60 combines the first portion of the data compressed multichannel extension signal and the remaining portions of the data compressed multichannel extension signal received at the second and first inputs, respectively, and generates a multichannel extension signal. And to supply to output 64. This output 64 is connected to the input 66 of the decompression unit 68.

The decompression unit 68 is configured to decompress the data compressed multichannel extension signal received at the input 66 into a multichannel extension signal. The output 70 of the decompression unit is connected to the second output terminal 72 of the device. The second output terminal 72 can be connected to a power amplifier, equalizer or speaker system.

The operation of the playback apparatus will be described in more detail below. The recording medium 42 having a stereo signal and a multichannel extension signal includes a first channel having a composite signal including a first portion of the stereo signal and the multichannel extension signal, and a second channel having the remainder of the multichannel extension signal. It is provided. The first channel is represented by the first variation of the first physical parameter of the record carrier and the second channel is represented by the second variation of the second physical parameter. The first channel is preferably on a standard CD with stereo signals. The first reading unit 40 reads the composite signal from the first channel of the recording medium by detecting the first variation of the first physical parameter of the recording medium. The composite signal includes a first portion of the stereo signal and the data compressed multichannel signal. Therefore, the composite signal can be supplied directly to the first output terminal for reproduction of the stereo signal. In such a case, the converter 74 is unnecessary. The extractor 50 is configured to extract the first data compressed multichannel extension signal from the composite signal.

The second reading section 54 reads the remaining portion of the data compressed multichannel extension signal from the second channel by detecting a second change in the second physical parameter of the recording medium. If the variation in the second physical parameter has a form of variation in the width of the plurality of marks that are optically detectable, the variation in the width of the mark causes additional intensity modulation of the radiation beam scanning the track. In a standard CD player, only the intensity modulation due to the variation of the first physical parameter can be detected from the radiation beam. An apparatus for detecting a second channel in the form of a change in track position in a direction transverse to the track direction is disclosed in US 5,724,327. The combiner 60 is configured to combine the first portion and the remaining portion of the data compressed multichannel extension signal. The combiner 60 preferably performs multiplexing of the first portion and the remaining portions to obtain a data compressed multipanel extension signal. The data compressed multichannel extension signal may be an MPEG2 audio stream generated by an MPEG-2 audio encoder. The multichannel extension signal includes, for example, a left signal, a right signal, a center signal, a surround left signal and a surround right signal. This multichannel extension signal is given to the second output terminal for reproduction by the speaker system, for example.

3 shows another embodiment of the first and second recording means in the recording apparatus shown in FIG. The channel modulator 302 receives the composite signal given to its input, and processes the composite signal to obtain a sequence of m-bit channel words. Preferably, the channel modulator comprises an n-m channel modulator. The generator 304 receives the remaining part given its input and generates p merge bits in response to the remaining part. The device 306 receives a sequence of m-bit channel words and p merge bits and inserts p merge bits between adjacent m-bit channel words to obtain a signal to be recorded on the recording medium 32. The p merge bits are generally used to prevent (d, k) constraint violations between adjacent channel words, and for the additional action of DC control. A method of generating p merge bits with additional signals and preventing (d, k) constraint violations between adjacent channel words is disclosed in unpublished patent application EP 99202061 (PHN 17.520). The data capacity of the additional signal thus obtained is used to hold the rest. The first recording unit 28 of the apparatus shown in FIG. 1 includes apparatus having reference numerals 302 and 306. The second recording section 34 of the apparatus shown in FIG. 1 includes apparatus having reference numerals 304 and 306.

4 shows another embodiment of the first and second reading means in the playback device shown in FIG. The device 402 reads the reproduction signal from the recording medium 32. The reproduction signal always contains a sequence of m-bit bichannel channel words having p merge bits between adjacent m-bit channel words. The device 402 divides the reproduction signal into a sequence of m-bit channel words and the p merge bits. The sequence of m-bit channel words is preferably given to a channel aid 404 configured to m-n channel modulate to obtain a composite signal. The composite signal in the form of a standard digital stereo signal is supplied to the output terminal 44. The p merge bits are given to the signal processor 406. The signal processor 406 is configured to signal-process the p merge bits to obtain the remaining portion for supplying to the output terminal 56. In the apparatus shown in FIG. 2, the first reading section 40 comprises a device having the reference numerals 402 and 404. In the device shown in FIG. 2, the second reading section 54 comprises devices having reference numerals 402 and 406.

FIG. 5 shows a second embodiment of the first and second recording means in the recording apparatus shown in FIG. The signal processing unit 502 receives the composite signal given to its input, and processes the composite signal to obtain a sequence of q byte blocks. The signal processor may include a cross-interleaved Reed-Solomon encoder. Subcode encoder 504 receives the remainder given to its input and generates an r byte subcode in response to the remainder described above. In the standard CD format, subcodes basically correspond to auxiliary data streams. At least one bit of the above r byte subcode, such as a U-subcode, is obtained in response to the remainder. The device 506 receives the sequence of q byte blocks and the r byte subcodes described above, and inserts the r byte subcodes between adjacent m-bit channel words to obtain a signal to be recorded on the recording medium 32. . Preferably, prior to recording said signal on the record carrier, this signal is channel encoded, for example by an EFM encoder. In the apparatus shown in FIG. 1, the first recording unit 28 includes apparatuses having the reference numerals 502 and 506. In the apparatus shown in FIG. 1, the second recording unit 34 includes apparatuses having the numerals 504 and 506.

FIG. 6 shows a second embodiment of the first and second reading means in the playback device shown in FIG. The device 602 reads out the reproduction signal from the recording medium 32. The playback signal always contains a sequence of q byte blocks with r byte subcodes between adjacent q byte blocks. The device 602 divides the reproduction signal into a sequence of q byte blocks and the r byte subcode. Such division is based on the physical location of q-byte blocks and subcodes in the reproduction signal. The sequence of q byte blocks is given to a signal processor 604 configured to signal process the sequence of q byte blocks to obtain a composite signal. The signal processor may perform Reed-Solomon decoding and de-cross-interleaving operations. The composite signal in the form of a standard digital stereo signal is supplied to the output terminal 44. The r byte subcode is given to the signal processor 606. The signal processing unit 606 is configured to signal process the r byte subcodes to obtain the remaining part from at least one bit of the r byte subcodes. This remaining part is supplied to the output terminal 56. In the apparatus shown in Fig. 2, the first reading portion 40 includes a device having reference numerals 602 and 604. In the apparatus shown in FIG. 2, the second reader 54 comprises apparatus having the numerals 602 and 606.

Although the present invention has been described with reference to preferred embodiments of the invention, it is clear that these embodiments are not examples given to limit the invention. Accordingly, various modifications may be made by those skilled in the art without departing from the scope of the invention described in the claims. As an example, the multi-channel extension signal including the left signal, the right signal, the center signal, the surround left signal, and the surround right signal may be an extension signal including image, video, or computer data. Furthermore, in another embodiment, the divider may be configured to scramble the data compressed multichannel extension signal into a scrambled signal, and generate the first portion including the scrambled signal and the remaining portion including the scrambling key. In another embodiment of the record carrier, the first portion includes a center signal and the remaining portion includes a surround left signal and a surround right signal. Channel modulators other than the n-m modulator described above may be used.

The term 'comprises' does not exclude the presence of elements or steps other than those listed in a claim. Also, reference numerals do not limit the scope of the present invention. The present invention can be implemented using hardware and software. Multiple "means" may be represented by the same item of hardware. Moreover, the present invention encompasses all novel features or combinations of these features.

Claims (26)

A recording medium having a data signal and a stereo signal recorded on a first channel, The data signal having a first portion coupled to the stereo signal to obtain a composite signal recorded on the first channel on the recording medium, and the remaining portion recorded on a second channel on the recording medium, Wherein the first channel is indicated by a first change in the first physical parameter of the record carrier and the second channel is indicated by a second change in the second physical parameter of the record carrier that is different from the first physical parameter. Recording medium, characterized in that. The method of claim 1, And the first portion is combined with the stereo signal using an embedded data technique. The method according to claim 1 or 2, And the data signal comprises a data compressed multichannel extension signal corresponding to an indication of the multichannel extension signal. The method of claim 3, wherein And the multichannel extension signal comprises a center channel signal. The method of claim 3, wherein The multi-channel extension signal includes a surround left signal and a surround right signal. The method of claim 3, wherein And the data compressed multichannel extension signal corresponds to a perceptually encoded representation of the multichannel extension signal. The method of claim 3, wherein And the first portion represents an indication of a portion of the multichannel extension signal. delete delete delete delete A method of recording a stereo signal and a data signal on a recording medium, Recording the stereo signal in a first channel on the record carrier, Dividing the data signal into a first part and the remaining part; Recording the remaining portion of the data signal to a second channel on a record carrier; Combining the first portion with the stereo signal to obtain a composite signal before recording the stereo signal on the first channel; Recording the composite signal on the first channel, The first channel is recorded on the recording medium by a first variation of the first physical parameter of the recording medium, And said second channel is recorded on said recording medium by a second variation of a second physical parameter of said recording medium different from said first physical parameter. The method of claim 12, Said combining step is performed using an embedded data technique. The method according to claim 12 or 13, And the recording method further comprises compressing the multichannel extension signal into a data signal. delete delete delete A recording apparatus for performing the method according to claim 12 or 13. A reproduction apparatus for reproducing a stereo signal and a data signal from a recording medium, First reading means for reading a first reproduction signal from a first channel on the recording medium; Extracting means for extracting a first portion of data from said first reproduced signal; Second reading means for reading the remainder of the data signal from the second channel on the record carrier; Combining means for combining the first portion and the remaining portion to obtain a data signal; Means for converting said first reproduced signal into said stereo signal, The first reading means is configured to read a stereo signal from the first channel by detecting a first change in a first physical parameter of the recording medium, And the second reading means is configured to read the remaining part of the data signal from the second channel by detecting a second change in the second physical parameter of the recording medium different from the first physical parameter. The method of claim 19, And said extracting means is configured to extract a first portion of a data signal from said first reproduced signal using an embedded data technique. The method of claim 19 or 20, The data signal includes a data compressed multichannel extension signal, and the apparatus includes: A decompression means for decompressing the data compressed multichannel extension signal into a multichannel extension signal. The method of claim 21, And said decompressing means is configured to decompress a data compressed multichannel extension signal comprising a center channel signal. The method of claim 21, And said decompressing means is configured to decompress a data compressed multichannel extension signal comprising a surround left signal and a surround right signal. delete delete delete

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